Unusual anticodon loop structure found in E.coli lysine tRNA.

Although both tRNA(Lys) and tRNA(Glu) of E. coli possess similar anticodon loop sequences, with the same hypermodified nucleoside 5-methylaminomethyl-2-thiouridine (mnm5s2U) at the first position of their anticodons, the anticodon loop structures of these two tRNAs containing the modified nucleoside appear to be quite different as judged from the following observations. (1) The CD band derived from the mnm5s2U residue is negative for tRNA(Glu), but positive for tRNA(Lys). (2) The mnm5s2U monomer itself and the mnm5s2U-containing anticodon loop fragment of tRNA(Lys) show the same negative CD bands as that of tRNA(Glu). (3) The positive CD band of tRNA(Lys) changes to negative when the temperature is raised. (4) The reactivity of the mnm5s2U residue toward H2O2 is much lower for tRNA(Lys) than for tRNA(Glu). These features suggest that tRNA(Lys) has an unusual anticodon loop structure, in which the mnm5s2U residue takes a different conformation from that of tRNA(Glu); whereas the mnm5s2U base of tRNA(Glu) has no direct bonding with other bases and is accessible to a solvent, that of tRNA(Lys) exists as if in some way buried in its anticodon loop. The limited hydrolysis of both tRNAs by various RNases suggests that some differences exist in the higher order structures of tRNA(Lys) and tRNA(Glu). The influence of the unusual anticodon loop structure observed for tRNA(Lys) on its function in the translational process is also discussed.     

Biosynthesis of 5-methylaminomethyl-2-selenouridine, a naturally occurring nucleoside in Escherichia coli tRNA

A selenium-containing nucleoside, 5-methylaminomethyl-2-selenouridine (mnm5se2U), is present in lysine- and glutamate-isoaccepting tRNA species of Escherichia coli. The synthesis of mnm5se2U is optimum (4 mol/100 mol tRNA) when selenium is present at about 1 microM concentration and is neither decreased by a high (8 mM) level of sulfur in the medium nor increased by excessive (10 or 100 microM) levels of selenium. Lysine- and glutamate-isoaccepting tRNA species that contain 5-methylaminomethyl-2-thiouridine (mnm5s2U) coexist with the seleno-tRNAs in E. coli cells and a reciprocal relationship between the mnm5se2U- and the mnm5s2U-containing species is maintained under a variety of growth conditions. The complete 5-methylaminomethyl side chain is not a prerequisite for introduction of selenium at the 2-position. In E. coli mutants deficient in the ability to synthesize the 5-methylaminomethyl substituent, both the 2-thiouridine and the corresponding 2-selenouridine derivatives of intermediate forms are accumulated. Broken cell preparations of E. coli synthesize mnm5se2U in tRNAs by an ATP-dependent process that appears to involve the replacement of sulfur in mnm5s2U with selenium.     

The cysteine desulfurase IscS is required for synthesis of all five thiolated nucleosides present in tRNA from Salmonella enterica serovar typhimurium

Deficiency of a modified nucleoside in tRNA often mediates suppression of +1 frameshift mutations. In Salmonella enterica serovar Typhimurium strain TR970 (hisC3737), which requires histidine for growth, a potential +1 frameshifting site, CCC-CAA-UAA, exists within the frameshifting window created by insertion of a C in the hisC gene. This site may be suppressed by peptidyl-tRNAProcmo5UGG (cmo(5)U is uridine-5-oxyacetic acid), making a frameshift when decoding the near-cognate codon CCC, provided that a pause occurs by, e.g., a slow entry of the tRNAGlnmnm5s2UUG (mnm(5)s(2)U is 5-methylaminomethyl-2-thiouridine) to the CAA codon located in the A site. We selected mutants of strain TR970 that were able to grow without histidine, and one such mutant (iscS51) was shown to have an amino acid substitution in the L-cysteine desulfurase IscS. Moreover, the levels of all five thiolated nucleosides 2-thiocytidine, mnm(5)s(2)U, 5-carboxymethylaminomethyl-2-thiouridine, 4-thiouridine, and N-6-(4-hydroxyisopentenyl)-2-methylthioadenosine present in the tRNA of S. enterica were reduced in the iscS51 mutant. In logarithmically growing cells of Escherichia coli, a deletion of the iscS gene resulted in nondetectable levels of all thiolated nucleosides in tRNA except N-6-(4-hydroxyisopentenyl)-2-methylthioadenosine, which was present at only 1.6% of the wild-type level. After prolonged incubation of cells in stationary phase, a 20% level of 2-thiocytidine and a 2% level of N-6-(4-hydroxyisopentenyl)-2-methylthioadenosine was observed, whereas no 4-thiouridine, 5-carboxymethylaminomethyl-2-thiouridine, or mnm(5)s(2)U was found. We attribute the frameshifting ability mediated by the iscS51 mutation to a slow decoding of CAA by the tRNAGlnmnm5s2UUG due to mnm(5)s(2)U deficiency. Since the growth rate of the iscS deletion mutant in rich medium was similar to that of a mutant (mnmA) lacking only mnm(5)s(2)U, we suggest that the major cause for the reduced growth rate of the iscS deletion mutant is the lack of mnm(5)s(2)U and 5-carboxymethylaminomethyl-2-thiouridine and not the lack of any of the other three thiolated nucleosides that are also absent in the iscS deletion mutant.     

Selenium-containing tRNA(Glu) and tRNA(Lys) from Escherichia coli: purification, codon specificity and translational activity

In response to low (approximately 1 microM) levels of selenium, Escherichia coli synthesizes tRNA(Glu) and tRNA(Lys) species that contain 5-methylaminomethyl-2-selenouridine (mnm5Se2U) instead of 5-methylaminomethyl-2-thiouridine (mnm5S2U). Purified glutamate- and lysine-accepting tRNAs containing either mnm5Se2U (tRNA(SeGlu), tRNA(SeLys] or mnm5S2U (tRNA(SGlu), tRNA(SLys] were prepared by RPC-5 reversed-phase chromatography, affinity chromatography using anti-AMP antibodies and DEAE-5PW ion-exchange HPLC. Since mnm5Se2U, like mnm5S2U, appears to occupy the wobble position of the anticodon, the recognition of glutamate codons (GAA and GAG) and lysine codons (AAA and AAG) was studied. While tRNA(SGlu) greatly preferred GAA over GAG, tRNA(SeGlu) showed less preference. Similarly, tRNA(SGlu) preferred AAA over AAG, while tRNA(SeLys) did not. In a wheat germ extract--rabbit globin mRNA translation system, incorporation of lysine and glutamate into protein was generally greater when added as aminoacylated tRNA(Se) than as aminoacylated tRNA(S). In globin mRNA the glutamate and lysine codons GAG and AAG are more numerous than GAA and AAA, thus a more efficient translation of globin message with tRNA(Se) might be expected because of facilitated recognition of codons ending in G.     

Selenomodification of tRNA in archaea requires a bipartite rhodanese enzyme

5-Methylaminomethyl-2-selenouridine (mnm(5)Se(2)U) is found in the first position of the anticodon in certain tRNAs from bacteria, archaea and eukaryotes. This selenonucleoside is formed in Escherichia coli from the corresponding thionucleoside mnm(5)S(2)U by the monomeric enzyme YbbB. This nucleoside is present in the tRNA of Methanococcales, yet the corresponding 2-selenouridine synthase is unknown in archaea and eukaryotes. Here we report that a bipartite ybbB ortholog is present in all members of the Methanococcales. Gene deletions in Methanococcus maripaludis and in vitro activity assays confirm that the two proteins act in trans to form in tRNA a selenonucleoside, presumably mnm(5)Se(2)U. Phylogenetic data suggest a primal origin of seleno-modified tRNAs.     

Sequence evidence in the archaeal genomes that tRNAs emerged through the combination of ancestral genes as 5' and 3' tRNA halves

The discovery of separate 5' and 3' halves of transfer RNA (tRNA) molecules-so-called split tRNA-in the archaeal parasite Nanoarchaeum equitans made us wonder whether ancestral tRNA was encoded on 1 or 2 genes. We performed a comprehensive phylogenetic analysis of tRNAs in 45 archaeal species to explore the relationship between the three types of tRNAs (nonintronic, intronic and split). We classified 1953 mature tRNA sequences into 22 clusters. All split tRNAs have shown phylogenetic relationships with other tRNAs possessing the same anticodon. We also mimicked split tRNA by artificially separating the tRNA sequences of 7 primitive archaeal species at the anticodon and analyzed the sequence similarity and diversity of the 5' and 3' tRNA halves. Network analysis revealed specific characteristics of and topological differences between the 5' and 3' tRNA halves: the 5' half sequences were categorized into 6 distinct groups with a sequence similarity of >80%, while the 3' half sequences were categorized into 9 groups with a higher sequence similarity of >88%, suggesting different evolutionary backgrounds of the 2 halves. Furthermore, the combinations of 5' and 3' halves corresponded with the variation of amino acids in the codon table. We found not only universally conserved combinations of 5'-3' tRNA halves in tRNA(iMet), tRNA(Thr), tRNA(Ile), tRNA(Gly), tRNA(Gln), tRNA(Glu), tRNA(Asp), tRNA(Lys), tRNA(Arg) and tRNA(Leu) but also phylum-specific combinations in tRNA(Pro), tRNA(Ala), and tRNA(Trp). Our results support the idea that tRNA emerged through the combination of separate genes and explain the sequence diversity that arose during archaeal tRNA evolution.     

Formation of thiolated nucleosides present in tRNA from Salmonella enterica serovar Typhimurium occurs in two principally distinct pathways

tRNA from Salmonella enterica serovar Typhimurium contains five thiolated nucleosides, 2-thiocytidine (s(2)C), 4-thiouridine (s(4)U), 5-methylaminomethyl-2-thiouridine (mnm(5)s(2)U), 5-carboxymethylaminomethyl-2-thiouridine (cmnm(5)s(2)U), and N-6-(4-hydroxyisopentenyl)-2-methylthioadenosine (ms(2)io(6)A). The levels of all of them are significantly reduced in cells with a mutated iscS gene, which encodes the cysteine desulfurase IscS, a member of the ISC machinery that is responsible for [Fe-S] cluster formation in proteins. A mutant (iscU52) was isolated that carried an amino acid substitution (S107T) in the IscU protein, which functions as a major scaffold in the formation of [Fe-S] clusters. In contrast to the iscS mutant, the iscU52 mutant showed reduced levels of only two of the thiolated nucleosides, ms(2)io(6)A (10-fold) and s(2)C (more than 2-fold). Deletions of the iscU, hscA, or fdx genes from the isc operon lead to a similar tRNA thiolation pattern to that seen for the iscU52 mutant. Unexpectedly, deletion of the iscA gene, coding for an alternative scaffold protein for the [Fe-S] clusters, showed a novel tRNA thiolation pattern, where the synthesis of only one thiolated nucleoside, ms(2)io(6)A, was decreased twofold. Based on our results, we suggest two principal distinct routes for thiolation of tRNA: (i) a direct sulfur transfer from IscS to the tRNA modifying enzymes ThiI and MnmA, which form s(4)U and the s(2)U moiety of (c)mnm(5)s(2)U, respectively; and (ii) an involvement of [Fe-S] proteins (an unidentified enzyme in the synthesis of s(2)C and MiaB in the synthesis of ms(2)io(6)A) in the transfer of sulfur to the tRNA.     

Structural alterations of the cysteine desulfurase IscS of Salmonella enterica serovar Typhimurium reveal substrate specificity of IscS in tRNA thiolation

The cysteine desulfurase IscS in Salmonella enterica serovar Typhimurium is required for the formation of all four thiolated nucleosides in tRNA, which is thought to occur via two principally different biosynthetic pathways. The synthesis of 4-thiouridine (s(4)U) and 5-methylaminomethyl-2-thiouridine (mnm(5)s(2)U) occurs by a transfer of sulfur from IscS via various proteins to the target nucleoside in the tRNA, and no iron-sulfur cluster protein participates, whereas the synthesis of 2-thiocytidine (s(2)C) and N(6)-(4-hydroxyisopentenyl)-2-methylthioadenosine (ms(2)io(6)A) is dependent on iron-sulfur cluster proteins, whose formation and maintenance depend on IscS. Accordingly, inactivation of IscS should result in decreased synthesis of all thiolated nucleosides. We selected mutants defective either in the synthesis of a thiolated nucleoside (mnm(5)s(2)U) specific for the iron-sulfur protein-independent pathway or in the synthesis of a thiolated nucleoside (ms(2)io(6)A) specific for the iron-sulfur protein-dependent pathway. Although we found altered forms of IscS that influenced the synthesis of all thiolated nucleosides, consistent with the model, we also found mutants defective in subsets of thiolated nucleosides. Alterations in the C-terminal region of IscS reduced the level of only ms(2)io(6)A, suggesting that the synthesis of this nucleoside is especially sensitive to minor aberrations in iron-sulfur cluster transfer activity. Our results suggest that IscS has an intrinsic substrate specificity in how it mediates sulfur mobilization and/or iron-sulfur cluster formation and maintenance required for thiolation of tRNA.     

Biochemistry of selenium-derivatized naturally occurring and unnatural nucleic acids

Selenium (Se) can provide unique biochemical and biological functions, and properties to macromolecules, including protein and RNA. Although Se has not yet been found in DNA, identification of the presence of Se in natural tRNAs has led to discovery of the naturally occurring 2-selenouridine and 5-[(methylamino)methyl]-2-selenouridine (mnm(5)se(2)U). The Se-atoms at C(2) of the modified uridines are introduced by 2-selenouridine synthase via displacement of the S-atoms in the corresponding 2-thiouridine nucleotides of the tRNAs, and selenophosphate is used as the Se donor. The research indicated that mnm(5)se(2)U is located at the first or wobble position of the anticodons in several bacterial tRNAs, including tRNA(Lys), tRNA(Glu), and tRNA(Gln). The 2-seleno functionality on this modified nucleotide probably improves the translation accuracy and/or efficiency. These observations in vivo suggest that the presence of Se can provide natural RNAs with useful properties to better function and survival. To further investigate the biochemical and structural properties of Se-derivatized nucleic acids (SeNA), we have pioneered chemical and enzymatic synthesis of Se-derivatized nucleic acids, and introduced Se into both RNA and DNA at a variety of positions by atom-specific replacement of oxygen. This review outlines the recent advancements in chemical and biochemical syntheses, and studies of SeNAs, and their potential applications in structural and functional investigation of nucleic acids and their protein complexes.     

Wobble modification differences and subcellular localization of tRNAs in Leishmania tarentolae: implication for tRNA sorting mechanism

In Leishmania tarentolae, all mitochondrial tRNAs are encoded in the nuclear genome and imported from the cytosol. It is known that tRNA(Glu)(UUC) and tRNA(Gln)(UUG) are localized in both cytosol and mitochondria. We investigated structural differences between affinity-isolated cytosolic (cy) and mitochondrial (mt) tRNAs for glutamate and glutamine by mass spectrometry. A unique modification difference in both tRNAs was identified at the anticodon wobble position: cy tRNAs have 5-methoxycarbonylmethyl-2- thiouridine (mcm(5)s(2)U), whereas mt tRNAs have 5- methoxycarbonylmethyl-2'-O-methyluridine (mcm(5)Um). In addition, a trace portion (4%) of cy tRNAs was found to have 5-methoxycarbonylmethyluridine (mcm(5)U) at its wobble position, which could represent a common modification intermediate for both modified uridines in cy and mt tRNAs. We also isolated a trace amount of mitochondria-specific tRNA(Lys)(UUU) from the cytosol and found mcm(5)U at its wobble position, while its mitochondrial counterpart has mcm(5)Um. Mt tRNA(Lys) and in vitro transcribed tRNA(Glu) were imported much more efficiently into isolated mitochondria than the native cy tRNA(Glu) in an in vitro importation experiment, indicating that cytosol-specific 2-thiolation could play an inhibitory role in tRNA import into mitochondria.     

Dependence of M1 RNA substrate specificity on magnesium ion concentration.

We have constructed a plasmid expressing E. coli M1 RNA, the catalytic RNA subunit of ribonuclease P, under the control of a phage T7 promoter. The active M1 RNA species synthesized in vitro by T7 RNA polymerase from this vector was reacted with the tRNA(Gln) - tRNA(Leu) precursor RNA (Band K) encoded by phage T4. Only the tRNA(Leu) moiety of this dimeric precursor RNA contains the 3' terminal C-C-A sequence common to all tRNAs. We observed that protein-free M1 RNA was capable of processing the precursor RNA at the 5' ends of both tRNA tRNA sequences. The rate of cleavage of the tRNA(Gln) sequence was more strongly dependent on [Mg2+] than that of tRNA(Leu), increasing severalfold between 100 and 500 mM Mg2+, conditions under which the rate of cleavage at the tRNA(Leu) sequence was constant.     

Functional diversity of the rhodanese homology domain: the Escherichia coli ybbB gene encodes a selenophosphate-dependent tRNA 2-selenouridine synthase

Escherichia coli has eight genes predicted to encode sulfurtransferases having the active site consensus sequence Cys-Xaa-Xaa-Gly. One of these genes, ybbB, is frequently found within bacterial operons that contain selD, the selenophosphate synthetase gene, suggesting a role in selenium metabolism. We show that ybbB is required in vivo for the specific substitution of selenium for sulfur in 2-thiouridine residues in E. coli tRNA. This modified tRNA nucleoside, 5-methylaminomethyl-2-selenouridine (mnm(5)se(2)U), is located at the wobble position of the anticodons of tRNA(Lys), tRNA(Glu), and tRNA(1)(Gln). Nucleoside analysis of tRNAs from wild-type and ybbB mutant strains revealed that production of mnm(5)se(2)U is lost in the ybbB mutant but that 5-methylaminomethyl-2-thiouridine, the mnm(5)se(2)U precursor, is unaffected by deletion of ybbB. Thus, ybbB is not required for the initial sulfurtransferase reaction but rather encodes a 2-selenouridine synthase that replaces a sulfur atom in 2-thiouridine in tRNA with selenium. Purified 2-selenouridine synthase containing a C-terminal His(6) tag exhibited spectral properties consistent with tRNA bound to the enzyme. In vitro mnm(5)se(2)U synthesis is shown to be dependent on 2-selenouridine synthase, SePO(3), and tRNA. Finally, we demonstrate that the conserved Cys(97) (but not Cys(96)) in the rhodanese sequence motif Cys(96)-Cys(97)-Xaa-Xaa-Gly is required for 2-selenouridine synthase in vivo activity. These data are consistent with the ybbB gene encoding a tRNA 2-selenouridine synthase and identifies a new role for the rhodanese homology domain in enzymes.     

Accurate translation of the genetic code depends on tRNA modified nucleosides

Transfer RNA molecules translate the genetic code by recognizing cognate mRNA codons during protein synthesis. The anticodon wobble at position 34 and the nucleotide immediately 3' to the anticodon triplet at position 37 display a large diversity of modified nucleosides in the tRNAs of all organisms. We show that tRNA species translating 2-fold degenerate codons require a modified U(34) to enable recognition of their cognate codons ending in A or G but restrict reading of noncognate or near-cognate codons ending in U and C that specify a different amino acid. In particular, the nucleoside modifications 2-thiouridine at position 34 (s(2)U(34)), 5-methylaminomethyluridine at position 34 (mnm(5)U(34)), and 6-threonylcarbamoyladenosine at position 37 (t(6)A(37)) were essential for Watson-Crick (AAA) and wobble (AAG) cognate codon recognition by tRNA(UUU)(Lys) at the ribosomal aminoacyl and peptidyl sites but did not enable the recognition of the asparagine codons (AAU and AAC). We conclude that modified nucleosides evolved to modulate an anticodon domain structure necessary for many tRNA species to accurately translate the genetic code.     

Wheat germ tRNAs containing uridine in place of ribothymidine: a characterization of an unusual class of eukaryotic tRNAs.

An unusual class of wheat germ tRNAs has been isolated which completely lacks ribothymidine (rT) and contains an unmodified uridine in its place. We discuss here the isolation, identification and properties of these tRNAs. The rT-lacking tRNAs of wheat germ are essentially limited to the glycine isoacceptors (a minimum of five identifiable species), three threonine and at least, one tyrosine tRNA. All tRNAs were obtained 70-100% pure by chromatographic methods, and were detected by their ability to be methylated by E. coli rT-forming uracil methyltransferase with methyl-labeled S-adenosyl-L-methionine (SAM) as the methyl donor. In vitro methylation of each of the tRNAs resulted in the formation of 1 mole of rT per mole of tRNA. In the one case analyzed in detail (tRNA1Gly), all of the rT was found to be located at the 23rd position from the 3' end of the tRNA molecule. Following complete digestion of four highly purified glycine isoacceptors (tRNAGly1,4,5,6) to nucleosides and subsequent periodate oxidation and 3H potassium borohydride reduction, all were found to contain an unusually high level of 5-methylcytidine (m5C) (3-4 residues per molecule), and all contained no rT. The possible correlation between the presence of m5C and the absence of rT is discussed. All of the chromatographically purified glycine tRNAs function in a wheat germ cell-free protein synthesizing system and polymerize glycine in response to either poly G or poly (G, U).     

Codon recognition patterns as deduced from sequences of the complete set of transfer RNA species in Mycoplasma capricolum. Resemblance to mitochondria

The nucleotide sequences of the complete set of tRNA species in Mycoplasma capricolum, a derivative of Gram-positive eubacteria, have been determined. This bacterium represents the first genetic system in which the sequences of all the tRNA species have been determined at the RNA level. There are 29 tRNA species: three for Leu, two each for Arg, Ile, Lys, Met, Ser, Thr and Trp, and one each for the other 12 amino acids as judged from aminoacylation and the anticodon nucleotide sequences. The number of tRNA species is the smallest among all known genetic systems except for mitochondria. The tRNA anticodon sequences have revealed several features characteristic of M. capricolum. (1) There is only one tRNA species each for Ala, Gly, Leu, Pro, Ser and Val family boxes (4-codon boxes), and these tRNAs all have an unmodified U residue at the first position of the anticodon. (2) There are two tRNAThr species having anticodons UGU and AGU; the first positions of these anticodons are unmodified. (3) There is only one tRNA with anticodon ICG in the Arg family box (CGN); this tRNA can translate codons CGU, CGC and CGA. No tRNA capable of translating codon CGG has been detected, suggesting that CGG is an unassigned codon in this bacterium. (4) A tRNATrp with anticodon UCA is present, and reads codon UGA as Trp. On the basis of these and other observations, novel codon recognition patterns in M. capricolum are proposed. A comparatively small total, 13, of modified nucleosides is contained in all M. capricolum tRNAs. The 5' end nucleoside of the T psi C-loop (position 54) of all tRNAs is uridine, not modified to ribothymidine. The anticodon composition, and hence codon recognition patterns, of M. capricolum tRNAs resemble those of mitochondrial tRNAs.     

Conversion of mammalian tRNA 3' processing endoribonuclease to four-base-recognizing RNA cutters.

The spermidine-dependent, sequence-specific endoribonuclease (RNase 65) activities in mammalian cell extracts require both protein and 3' truncated tRNA, species of which direct their substrate sequence specificity. Computer analysis for searching possible base pairing between substrate RNAs and their corresponding 3' truncated tRNA, suggested a unified model for substrate recognition mechanism, in which a four-nucleotide (nt) sequence in the target tRNAs 1 nt upstream of their cleavage site, base pairs with the 5' terminal 4 nt sequence of their corresponding 3' truncated tRNA. This model was supported by experiments with several RNA substrates containing a substituted nucleotide in the target 4 nt sequence. In this model, the tRNA substrates and their corresponding 3' truncated tRNA form a complex resembling a 5' processed tRNA precursor containing a 3' trailer, suggesting that the protein component of RNase 65 is identical to tRNA 3' processing endoribonuclease (3' tRNase). Actually, 3' tRNase purified from pig liver cleaved the target RNAs at the expected sites only in the presence of their corresponding 3' truncated tRNA. These results show that the 3' tRNase can be converted to 4 nt specific RNA cutters using the 3' truncated tRNAs.     

The Kluyveromyces lactis gamma-toxin targets tRNA anticodons

Kluyveromyces lactis killer strains secrete a heterotrimeric toxin (zymocin), which causes an irreversible growth arrest of sensitive yeast cells. Despite many efforts, the target(s) of the cytotoxic gamma-subunit of zymocin has remained elusive. Here we show that three tRNA species tRNA(Glu)(mcm(5)s(2)UUC), tRNA(Lys)(mcm(5)s(2)UUU), and tRNA(Gln)(mcm(5)s(2)UUG) are the targets of gamma-toxin. The toxin inhibits growth by cleaving these tRNAs at the 3' side of the modified wobble nucleoside 5-methoxycarbonylmethyl-2-thiouridine (mcm(5)s(2)U). Transfer RNA lacking a part of or the entire mcm(5) group is inefficiently cleaved by gamma-toxin, explaining the gamma-toxin resistance of the modification-deficient trm9, elp1-elp6, and kti11-kti13 mutants. The K. lactis gamma-toxin is the first eukaryotic toxin shown to target tRNA.     

MnmA and IscS are required for in vitro 2-thiouridine biosynthesis in Escherichia coli

Thionucleosides are uniquely present in tRNA. In many organisms, tRNA specific for Lys, Glu, and Gln contain hypermodified 2-thiouridine (s(2)U) derivatives at wobble position 34. The s(2) group of s(2)U34 stabilizes anticodon structure, confers ribosome binding ability to tRNA and improves reading frame maintenance. Earlier studies have mapped and later identified the mnmA gene (formerly asuE or trmU) as required for the s(2)U modification in Escherichia coli. We have prepared a nonpolar deletion of the mnmA gene and show that it is not required for viability in E. coli. We also cloned mnmA from E. coli, and overproduced and purified the protein. Using a gel mobility shift assay, we show that MnmA binds to unmodified E. coli tRNA(Lys) with affinity in the low micromolar range. MnmA does not bind observably to the nonsubstrate E. coli tRNA(Phe). Corroborating this, tRNA(Glu) protected MnmA from tryptic digestion. ATP also protected MnmA from trypsinolysis, suggesting the presence of an ATP binding site that is consistent with analysis of the amino acid sequence. We have reconstituted the in vitro biosynthesis of s(2)U using unmodified E. coli tRNA(Glu) as a substrate. The activity requires MnmA, Mg-ATP, l-cysteine, and the cysteine desulfurase IscS. HPLC analysis of thiolated tRNA digests using [(35)S]cysteine confirms that the product of the in vitro reaction is s(2)U. As in the case of 4-thiouridine synthesis, purified IscS-persulfide is able to provide sulfur for in vitro s(2)U synthesis in the absence of cysteine. Small RNAs that represent the anticodon stem loops for tRNA(Glu) and tRNA(Lys) are substrates of comparable activity to the full length tRNAs, indicating that the major determinants for substrate recognition are contained within this region.     

15N and 13C labeling of Escherichia coli tRNAs toward the NMR analysis.

Escherichia coli tRNAs were labeled with stable isotope 15N in vivo. Three species of tRNA, tRNA(Glu), tRNA(Lys) and tRNA(Ile), were purified by an HPLC system and their NMR spectra were observed. In heteronuclear 1H-15N multiple or single quantum coherence (HMQC or HSQC) spectra, the crosspeaks corresponding to NH3 of U and NH1 of G can be distinguished clearly since their 15N chemical shifts are significantly different from each other. Thus, this combination of 15N-labeling and the proton detected heteronuclear experiments are useful for the signal assignment and the conformational analysis of tRNAs. Furthermore, C1'- selective 13C-labeling of nucleotides was examined in vivo in order to resolve the H1' signals of tRNAs. By using a newly constructed E. coli mutant strain, the isotopic enrichments of more than 90% at C1' and of less than 10% for other ribose carbons were achieved.